Semiconductor Device and Method for Fabricating the Same

ABSTRACT

A method for fabricating a semiconductor device comprises: performing a thermal process to expanding a local doped region formed between gate patterns on a semiconductor substrate; and etching a central region of an expanded local doped region so that the expanded local doped region remains at the total area of sidewalls of floating bodies isolated from each other.

CROSS-REFERENCE TO RELATED APPLICATION

The priority of Korean patent application number 10-2008-0049892 filedMay 28, 2008, the disclosure of which is incorporated by reference inits entirety, is claimed.

BACKGROUND OF THE INVENTION

The invention relates generally to a method for fabricating asemiconductor device and, more specifically, to a technology of forminga floating body transistor used in a highly-integrated semiconductordevice using a silicon-on-insulator (SOI) structure.

In many semiconductor device systems, a semiconductor memory apparatusis configured to store data generated or processed in the device. Forexample, if a request from a data processor such as a central processingunit (CPU) is received, a semiconductor memory apparatus may output datato the data processor from unit cells in the apparatus, or the apparatusmay store data processed by the data processor to unit cells of anaddress transmitted with the request.

As data storage capacities of semiconductor memory apparatus haveincreased, the sizes of semiconductor memory apparatus have notincreased proportionally. Thus, various elements and components used forread or write operations in a semiconductor memory apparatus have alsoreduced in size. Accordingly, components and elements unnecessarilyduplicated in the semiconductor memory apparatus, such as transistors orwires, are combined or merged to decrease the area occupied by eachcomponent. Particularly, the reduction of the size of unit cellsincluded in the semiconductor memory apparatus affects improvement ofthe degree of integration.

As an example of a semiconductor memory apparatus, Dynamic Random AccessMemory (DRAM) is a type of volatile memory device configured to retaindata while a power source is supplied. The unit cell comprises atransistor and a capacitor. In the case of the unit cell having acapacitor, after the datum “1” is delivered to the capacitor, chargesthat are temporarily stored in the storage node are dissipated, i.e.,the amount of the charge stored therein is reduced, because of bothleakage currents generated at junction of the storage nodes and inherentcharacteristics of the capacitor. As a result, a refresh operation isperiodically required on the unit cells so that data stored in the DRAMcannot be destroyed.

In order to prevent the reduction of charge, numerous methods forincreasing capacitance (Cs) of the capacitor included in the unit cellhave been suggested so that more charges may be stored in the storagenode. For example, an insulating film used earlier in the capacitor,e.g., an oxide film, may be replaced with an advanced insulating filmwhich has a larger dielectric constant, such as a nitrified oxide filmor a high dielectric film. Otherwise, a capacitor having atwo-dimensional structure is changed to have a three-dimensionalcylindrical structure or a trench structure, thereby increasing thesurface area of both electrodes of the capacitor.

As the design rule is reduced, the plane area where a capacitor can beformed is reduced, and it is difficult to develop materials constitutingan insulating film in the capacitor. As a result, the junctionresistance value of the storage node (SN) and the turn-on resistancevalue of the transistor in the unit cell are larger, and accordingly itis difficult to perform normal read and write operations, and refreshcharacteristics deteriorate.

To improve the above-described shortcomings, the unit cell may comprisea transistor having a floating body. Thus, the unit cell of thesemiconductor memory apparatus does not include a capacitor used forstoring data, but stores data in a floating body of the transistorincluded in the unit cell.

In order to store data in the floating body, a voltage level supplied onthe word line is reduced by ½ or ⅓ of voltage level applied to the bitline connected to one active region of the transistor, therebygenerating hot carriers. When the datum “1” is delivered, a large amountof hot carriers are generated in a junction region of the bit lines(BL). Then, electrons are sent out into the bit line (BL) but holesremain in the floating body (FB). Otherwise, when the datum “0” istransmitted, the hot carriers are not generated in the junction region,so that any holes do not remain in the floating body (FB). The holeskept in the floating body lower the threshold voltage of the transistorof the unit cell; as a result, the amount of current flowing through thetransistor increases. That is, the amount of current flowing when theholes are stored in the floating body of the transistor is larger thanthat flowing when no holes are stored. As a result, it is possible todistinguish whether the datum “1” or “0” is stored in the unit cell.

The semiconductor memory apparatus that comprises the floating bodytransistor does not include a capacitor, thereby improving the abilityto maximize the degree of integration. However, it is difficult toprevent reduction of the amount of holes that the floating body of theFB transistor stores, due to a leakage current that occurs at junctionsbetween the floating body and either a source line or a bit line.Generally, active regions of the transistor, which are connected to thebit line or the source line, include impurities of high concentration inorder to reduce resistance resulting from junction with metal layers.However, if the active region (e.g. source or drain region) of thetransistor is doped with impurities of high concentration, the amount ofleakage current between the active region and the floating body mayincrease. As a result, the amount of holes stored in the floating bodyis dissipated as time goes by. Also, since the amount of leakage currentincreases in proportion to temperature, data stored in the transistor ofthe unit cell are easily deleted under conditions of high temperature.

FIGS. 1 a to 1 e are cross-sectional diagrams illustrating a prior artmethod for manufacturing a floating body transistor in a semiconductormemory apparatus.

Referring to FIG. 1 a, a gate oxide film 132 is formed over an uppersilicon layer 114 of a silicon-on-insulator (SOI) semiconductorsubstrate. A gate pattern 120 that comprises a gate electrode includinga polysilicon layer 122, a metal layer 124, and a hard mask 116 forprotecting the gate electrode is formed. The SOI substrate comprises alower silicon layer 110, a lower insulating oxide layer 112 formed onthe lower silicon layer 110, and an upper silicon layer 114 formed on alower insulating oxide layer 112. The SOI wafer thus includes aninsulating layer 112 that is artificially formed between the uppersilicon layer 114, which is the top surface, and the lower silicon layer110, which is a basic layer, so as to remove the impact from the basiclayer, thereby improving the process, efficiency, and characteristics ofa high-pure silicon layer formed over the insulating layer. Since theSOI wafer provides a zero-defective thin silicon layer isolated with aninsulating layer (thermal oxide film), an insulating wall or awell-forming process is not required, so that the product developingtime, producing time, and cost are reduced. Also, there is no burden onequipment investment because the equipment that uses a general waferreduces unnecessary equipment.

After the gate pattern is formed, an ion implantation process isperformed (see the arrows in FIG. 1 b) on the upper silicon layer 114located at both sides of the gate pattern 120, thereby obtaining asource/drain region 130. In order to prevent a hot carrier effect (HCE),the source/drain region 130 is neither deeply formed nor expanded to alower portion of the gate pattern while the doping concentration islowered by the ion implantation process.

Referring again to FIG. 1 b, a local halo region 140 is formed at adeeper location than the source/drain region 130 in the upper siliconlayer 114 through the ion implantation process. The local halo region140 formed in the body of the transistor is a high concentration dopedregion that prevents a punch-through phenomenon between the source andthe drain. The local halo region 140 prevents the ion-implanted regionfrom diffusing into a space between the source/drain regions by thermaltreatment when a plug is formed in a subsequent process.

Referring to FIG. 1 c, a spacer 128 is formed at sidewalls of the gatepattern 120, and an oxide film 150 that protects the gate pattern isformed over the sidewalls and the gate pattern. The oxide film, whichhas been widely used to protect the gate pattern, is formed over thestructure including the gate pattern, and a self-aligned etching processis performed on the oxide film to obtain a cap-type oxide film 150 thatprotects the top surface of the gate pattern. An etch-back process isperformed to etch the gate oxide film 132 and the oxide film 150,thereby exposing the source/drain region 130.

Referring to FIG. 1 d, a doped polysilicon layer 160 that forms a plugis formed over the structure including the gate pattern 120. Thepolysilicon layer 160 contacts the gate pattern 120 and the source/drainregion 130.

Referring to FIG. 1 e, the doped polysilicon layer 160 is diffused intothe upper silicon layer 114 by thermal treatment, so that transistorscorresponding to each gate pattern 120 are separated, and a source and adrain of each transistor is defined. The diffused polysilicon layer 160a is diffused into the lower insulating oxide layer 112, so that a bodyof the neighboring transistor is completely isolated.

In the floating body transistor fabricated over the SOI wafer, it isadvantageous to isolate cells in a single active region rather than toisolate unit cells through a device isolation film by shallow trenchisolation (STI) process in order to maximize the cell packing density.However, when the entire size of the transistor is reduced, the distancebetween source/drain regions of the transistor having a plane channelregion is reduced to cause a punch-through phenomenon, which isdifficult to prevent this.

Referring again to FIG. 1 e, when the diffusion process is performed ata high temperature after the polysilicon film 160 of high concentrationis deposited, the polysilicon film 160 is diffused horizontally as wellas vertically, thereby obtaining the diffused polysilicon layer 160 athat serves as a plug. Due to the horizontal diffusion, the effectivevolume of the body of each transistor is reduced (that is, the effectivechannel length becomes shorter). Also, the punch-through phenomenon mayoccur in the top or bottom portion of the floating body formed in theupper silicon layer 114.

Specifically, the punch-through phenomenon frequently occurs in thebottom portion of the floating body having a lower concentration than inthe top portion of the floating body having a higher concentration bychannel doping when the gate pattern 120 is formed. In order to preventthe punch-through phenomenon, an ion tilt implantation process isperformed to form the local halo region 140 in the upper silicon layer114. As the distance between the neighboring gate patterns becomesshorter due to reduction of the design rule, the tilt angle is notsufficiently secured in the ion tilt implantation process, so that it isdifficult to form the local halo region 140 in the bottom portion of thefloating body. When the local halo region 140 is not formed in thebottom portion of the floating body, it is difficult to prevent thepunch-through phenomenon in the floating body of the transistor, therebydegrading the reliability of the device.

BRIEF SUMMARY OF THE INVENTION

Various embodiments of the invention are directed to providing asemiconductor device and a method for fabricating the same. In themethod, a local doped region instead of a halo doped region is formed attotal area of sidewalls of a floating body so that a short-channeleffect such as the punch-through phenomenon is prevented.

In one embodiment of the invention, a method for fabricating asemiconductor device comprises: expanding a local doped region formedbetween gate patterns by a thermal process to form an expanded localdoped region; and, etching a central region of the expanded local dopedregion so that the expanded local doped region entirely covers sidewallsof floating bodies formed beneath the gate patterns to isolate thefloating bodies from each other.

Preferably, the thermal process is performed until the local dopedregion is expanded in a vertical direction to a buried insulating layerin and horizontally to a predetermined region under a spacer forprotecting sidewalls of the gate patterns.

Preferably, the semiconductor substrate is a silicon-on-insulatorsubstrate and the method further comprises: performing an ionimplantation process on the silicon-on-insulator substrate exposedbetween the gate patterns to form the local doped region; and, forming aspacer at sidewalls of the gate patterns.

Preferably, the ion implantation process is performed at a tilt angle ofzero degrees.

Preferably, the method further comprises: forming a gate oxide layer onthe silicon-on-insulator substrate; and forming the gate patterns on thegate oxide layer.

Preferably, the method further comprises: depositing a conductivematerial in an etched central region of the expanded local doped regionto form a plug between the gate patterns.

Preferably, the method further comprises performing another thermalprocess after depositing the conductive material.

Preferably, the lower region of the floating body including the expandedlocal doped region is wider than an upper region thereof.

Preferably, the method further comprises forming oxide layers to protectthe gate patterns.

Preferably, etching a central region of an expanded local doped regionis carried out by an etch-back process to remove an exposed area of botha gate oxide layer and the expanded local doped region between the oxidelayers.

Preferably, the etch-back process is performed until a buried insulatinglayer included in a silicon-on-insulator substrate is exposed.

In another embodiment of the invention, a semiconductor device comprisesgate patterns, and floating bodies having sidewalls formed under each ofthe gate patterns, wherein a local doped region is formed to entirelycover the sidewalls of each floating body to isolate the floating bodiesfrom each other.

Preferably, the gate patterns are formed on a silicon-on-insulatorsubstrate and the floating bodies are formed in an upper silicon layeron a buried insulating layer included in the silicon-on-insulatorsubstrate.

Preferably, the local doped region is connected both to the buriedinsulating layer in a vertical direction and to a predetermined regionunder a spacer to protect sidewalls of the gate patterns in a horizontaldirection.

Preferably, the semiconductor device further comprises a gate oxidelayer formed between the gate patterns and the upper silicon layer.

Preferably, the local doped region formed at a lower region of thefloating body is wider than an upper region thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 a to 1 e are cross-sectional diagrams illustrating a prior artmethod for manufacturing a floating body transistor in a generalsemiconductor memory apparatus.

FIGS. 2 a to 2 g are cross-sectional diagrams illustrating a method formanufacturing a floating body transistor in a semiconductor memoryapparatus of an embodiment of the invention.

DESCRIPTION OF EMBODIMENTS

FIG. 2 a to 2 g are cross-sectional diagrams illustrating a method formanufacturing a floating body transistor for use in a semiconductormemory apparatus according to one embodiment of the invention.

Referring to FIG. 2 a, a gate oxide film 232 is formed over an uppersilicon layer 214 of an SOI semiconductor substrate. A gate pattern 220that includes a gate electrode comprising a polysilicon layer 222, ametal layer 224, and a hard mask 226 for protecting the gate electrodeis formed. The SOI substrate comprises a lower silicon layer 210, alower insulating oxide layer 212 formed on the lower silicon layer 210,and an upper silicon layer 214 formed on the lower insulating oxidelayer 212. Impurities are doped between the gate patterns 220 to form alightly doped drain (LDD) (not shown).

After the gate pattern 220 is formed, an ion implantation process isperformed on the upper silicon layer 214 located at both sides of thegate pattern 220, thereby obtaining a source/drain region 230. In orderto prevent a hot carrier effect (HCE), the source/drain region 230 isneither deeply formed nor expanded to a lower portion of the gatepattern while the doping concentration is decreased by the ionimplantation process.

Referring to FIG. 2 b, a spacer 228 is formed at sidewalls of the gatepattern 220. After the spacer 228 is formed, a local halo region 240 isformed in the bottom portion of the source/drain region 230 located atthe upper silicon layer 214 through an ion implantation process. Unlikethe conventional art, an ion-tilt implantation process is not performed;rather a vertical ion implantation process (i.e., a process wherein thetilt angle is zero degrees) is used to form the local halo region 240.As a result, it is easy to form the local halo region 240 in the bottomportion of the source/drain region 230 located between the neighboringgate patterns 220, even though the design rule is reduced.

Referring to FIG. 2 c, after the ion implantation process forms thelocal halo region 240, a thermal treatment process is performed. As aresult, the local halo region 240 is diffused vertically and thus isexpanded into the lower insulating oxide layer 212. The local haloregion 240 is also diffused horizontally to penetrate into the lowerregion of the spacer 228 formed at sidewalls of the gate pattern 220.

Referring to FIG. 2 d, an oxide film 250 that protects the gate patternis formed. The oxide film 250 is formed over the structure including thegate pattern, and a self-aligned etching process is performed, therebyforming a cap-type oxide film that protects the top surface of the gatepattern as shown in FIG. 2 d.

After the oxide film 250 is formed, an etch-back process is performed,as shown in FIG. 2 e, to etch the upper silicon layer 214 and the gateoxide film 232 exposed between the gate pattern 220 and the oxide film250 that protects the gate pattern, thereby exposing the lowerinsulating oxide layer 212. Since the local halo region 240 is formed inthe upper silicon layer 214 between the gate patterns 220, a centralregion of the local halo region 240 is etched so that a peripheralregion, which comes in contact with the body of the neighboringtransistor, remains. The etched local halo region 240 a remains in thebottom portion of the source/drain region 130 to prevent thepunch-through phenomenon in the floating body.

Referring to FIG. 2 e, the etched local halo region 240 a is notvertically aligned with the gate pattern but etched slantwise. Thus, thesilicon active region 214 and the local halo region 240 a that remain inthe lower region of the gate pattern 220 are formed in the shape of atrapezoid. Therefore, the upper portion is narrower than the lowerportion in the silicon active region 214, which may occur when amaterial deposited between narrow patterns is etched. It is notnecessary to perform a vertical etching process with an enhanced etchcondition, but it is sufficient to expose the lower insulating oxidelayer 212 and isolate the neighboring silicon active regions 214 thatremain in the lower region of each gate pattern 220. Particularly, asthe sidewall tilt of the etched local halo region 240 a is gradual, thevolume of the floating body of the transistor is larger, and it iseasier to prevent the punch-through phenomenon in the bottom of thefloating body having a lower doping concentration.

Referring to FIG. 2 f, a polysilicon material 260, which is conductive,is deposited over the gate pattern 220 and the region etched between thegate patterns. When a thermal treatment process is performed after thepolysilicon 260 is deposited, as shown in FIG. 2 g, the polysilicon 260of the plug region is diffused, thereby forming diffused polysilicon 260a. Although the upper portion of the etched local halo region 240 abecomes thinner than the lower portion thereof, the upper portion of thefloating body 214 a has a higher doping concentration than the lowerportion of the floating body 214 a, thereby preventing the punch-throughphenomenon.

In the conventional art, referring to FIG. 1 b, the ion tiltimplantation process is performed to form the local halo region 140 overthe upper silicon layer 114. Due to reduction of the design rule, theinterval between the neighboring gate patterns 120 is narrow, so that atilt angle is not readily secured in the ion tilt implantation process.As a result, it is difficult to form the local halo region 140. However,in the embodiment of the invention, the local halo region 240 is etchedslantwise to form a plug, so that the volume of the floating bodybecomes larger, thereby preventing the punch-through phenomenon that mayoccur in the bottom of the floating body.

As described above, in a floating body transistor fabricated in a SOIsubstrate of one embodiment of the invention, it is easy to isolate eachtransistor and to form a local halo region that prevents a punch-throughphenomenon at both sides of the floating body, thereby improving theintegration and stability of the semiconductor device. Particularly,when the floating body transistor is used as a cell transistor in asemiconductor memory apparatus, the integration of the semiconductormemory apparatus can be greatly improved.

The foregoing embodiments of the invention are illustrative and notlimiting. Various alternatives and equivalents are possible. Theinvention is not limited by the type of deposition, etching polishing,and patterning steps describe herein, nor is the invention limited toany specific type of semiconductor device. For example, the inventionmay be implemented in a dynamic random access memory (DRAM) device ornon-volatile memory device. Other additions, subtractions, ormodifications are intended to fall within the scope of the appendedclaims.

1. A method for fabricating a semiconductor device, comprising: performing a first thermal process on a local doped region formed between gate patterns on a semiconductor substrate to form an expanded local doped region; and etching a central region of the expanded local doped region to form an expanded local doped region entirely covering sidewalls of the floating bodies beneath the gate patterns to isolate the floating bodies from each other.
 2. The method of claim 1, comprising performing the thermal process until the local doped region is expanded vertically to a buried insulating layer and horizontally to a predetermined region under a spacer protecting sidewalls of the gate patterns.
 3. The method of claim 1, further comprising: forming the local doped region by performing an ion implantation process to the semiconductor substrate exposed between the gate patterns; and forming a spacer at the sidewalls of the gate patterns, wherein the semiconductor substrate is a silicon-on-insulator substrate.
 4. The method of claim 3, comprising performing the ion implantation process at a tilt angle of zero degrees.
 5. The method of claim 3, further comprising: forming a gate oxide layer on the silicon-on-insulator substrate; and forming the gate patterns on the gate oxide layer.
 6. The method of claim 1, further comprising depositing a conductive material in an etched central region of the expanded local doped region to form a plug between the gate patterns.
 7. The method of claim 6, further comprising performing a second thermal process after depositing the conductive material.
 8. The method of claim 1, wherein a lower region of the floating body including the expanded local doped region is wider than an upper region thereof.
 9. The method of claim 1, further comprising forming oxide layers that protect the gate patterns.
 10. The method of claim 8, wherein etching a central region of an expanded local doped region comprises an etch-back process to remove an exposed area of both a gate oxide layer and the expanded local doped region between the oxide layers.
 11. The method of claim 10, comprising performing the etch-back process until a buried insulating layer of the silicon-on-insulator substrate is exposed.
 12. A semiconductor device comprising gate patterns and floating bodies, each floating body being formed under each of the gate patterns and having sidewalls, wherein a local doped region is formed to entirely cover sidewalls of each floating body to isolate the floating bodies from each other.
 13. The semiconductor device of claim 12, wherein the gate patterns are formed on a silicon-on-insulator substrate and the floating bodies are formed in an upper silicon layer on a buried insulating layer included in the silicon-on-insulator substrate.
 14. The semiconductor device of claim 13, wherein the local doped region is connected to both the buried insulating layer in a vertical direction and to a predetermined region under a spacer for protecting sidewalls of the gate patterns in a horizontal direction.
 15. The semiconductor device of claim 12, further comprising a gate oxide layer formed between the gate patterns and the upper silicon layer.
 16. The semiconductor device of claim 12, wherein the local doped region formed at a lower region of the floating body is wider than an upper region thereof. 